Method and system of data packet transmission timing for controlling bandwidth

ABSTRACT

A method and system for determining a wait time (t w ) to be used between successive transmissions of packets of a content to achieve a selected target bandwidth B T  for the transmission. The wait time between successive packets of a content being transmitted is determined as a function of the selected target bandwidth (B T ) to be achieved during the transmission and the size (P) of the packets based on the algorithm 
     
       
         
           
             
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     The invention provides bandwidth control at the source (the sending device) without relying on network Quality of Service (QoS) facilities.

FIELD OF THE INVENTION

The invention relates to a method and system for timing the transmission of data packets from a sender device to one or more receiving devices, for achieving bandwidth control.

BACKGROUND OF THE INVENTION

In performing data transmission using various media such as cable, telephone line, satellite communication, etc., it is conventional for the data to be sent from one device to other devices. The data is first fragmented, or segmented, into packets and then the packets transmitted, or broadcast. The term “packet” is used to indicate a sequence of bytes and represents the smallest unit of transmission and reception. Hereafter, a “device” is defined as a hardware element with a software component capable of receiving and/or transmitting data packets. Examples of such devices include computers, GPRS mobile phones and network equipment.

The term “content”, as used herein, indicates data that is segmented into a sequence of packets. The data contained within the content could be a file, or part of a file, part of a data stream, or any collection of data. The content can be of pure data, or audio and video data streams, or of any combination. The content is sent in sequentially transmitted packets from a sender device to one or more receiving devices.

The sending and receiving devices typically run software programs, whose purpose at the sender device is to fragment the content to be sent into packets, and at the receiver device to reassemble the packets received into the original content.

Bandwidth is defined as the amount of data that can be transmitted over the media in a given time frame, for example, 10 Mbps (10 million bits per second). Essentially, this is the speed of the transmission, that is, the speed at which data is sent from the sending device to the receiving devices. Each transmitting-receiving system has a certain bandwidth capability that is defined by various factors, such as the type of media used for the transmission and equipment used for transmission and reception of the data. For example, a broadband cable medium has a larger bandwidth capability than a telephone line.

Various types of protocols are used to transmit the data packets forming the content. Some protocols may be considered to be “unreliable”, herein meaning any transmission protocol that provides best-effort delivery of packets, and in particular, does not perform automatic re-transmission of lost or corrupted packets. Examples of “unreliable” protocols currently in common use include unicast and multicast User Datagram Protocol (UDP), ATM Adaption Layer (AAL) Types 3/4 and 5 in non-assured transmission mode, AppleTalk DDP datagrams, and unicast and broadcast MPEG-2 transport streams.

Often, data from different files is to be transmitted at the same time over the same media. For example, if a particular system has a 10 Mbps bandwidth transmission capability, the packets of two different contents can be transmitted at the same time in separate streams, for example, each stream of 5 Mbps bandwidth. In various commercial applications, portions of the available bandwidth of a given media are sold or licensed to different customers for use at the same time.

Some applications require that packets are to be received in a regular and timely fashion, for example, for audio and video transmissions in which it is important that the jitter (i.e., the amount of variation in the end-to-end packet transit time) is kept as low as possible. Increasing reliability at the receiving device implies use of a high precision control of the bandwidth at the sending device, especially for broadband applications.

In general, the bandwidth usage of a broadcast application is selected according to network load and speed, leased bandwidth capacity, and processing speed of the receiving device. The bandwidth allocated for a given transmission is hereafter referred to as the “target bandwidth”. During the transmission, the actual bandwidth used can vary relative to the selected target bandwidth.

As the broadcast takes place, the bandwidth varies and can be measured at any time. “The instantaneous” bandwidth is the bandwidth measured in the shortest measurable time. For example, if the bandwidth usage can be regularly checked at most once per second, the instantaneous bandwidth is computed by dividing the quantity of data transferred in that time frame (in this case 1 second) by that time interval.

The broadcast of the content has an “average (or mean) bandwidth”. This is the total amount of data transmitted during a transmission divided by the transmission duration. The terms “mean bandwidth” and “average bandwidth” are used interchangeably herein.

Since the content is transmitted in packets, there is a pause, or wait time, between the start of transmission of successive packets. The wait time between packets is related to the bandwidth used during transmission of a content. For example, increasing the wait time between packets while maintaining a fixed packet size results in less data transmitted during a given time, and vice versa.

If data is sent without a precise bandwidth control, various problems can arise. Basically, there are three different scenarios that can cause trouble:

(1) the average bandwidth is too high relative to the target bandwidth value;

(2) the average bandwidth is too low relative to the target bandwidth value;

(3) the average bandwidth is equal, or very close, to the target bandwidth, but the instantaneous bandwidth values measured during the transmission are different from the target bandwidth. This type of transmission is hereafter referred to as heterogeneous, i.e., contains peaks.

The problems caused by the different scenarios described above can adversely affect different components and structures of the system that receive the data, such as routing and switching devices and the destination receiver devices. This is described below.

(1) Sending data packets too fast. Broadcasting of the data at a speed above the target bandwidth usually results in substantial packet losses. Loss of packets reduces the integrity of the data transmission. Also, too high a transmission speed can cause congestion if routing devices are not able to buffer the incoming data stream. The same problem can affect encapsulators if data is sent to a satellite uplink. Here, entire series of packets can be lost. At the receiving device side, packet reassembly can be difficult if the hardware or application program processing the received data is not designed for an incoming data stream speed higher than the bandwidth mean (average) value. Moreover, a local area network (LAN) to which the receiving devices are connected can experience congestion if no traffic buffering mechanism is provided between the data transmitter and the receiving devices.

(2) Sending data packets too slow. If the packets are transmitted at a speed lower than the specified target bandwidth, no losses of data packets should be experienced. However, a resource waste is caused, especially if the connection between the data transmitter and receiving devices is purchased on a bandwidth usage basis instead of on a transmitted data amount basis. Also, audio and video streaming quality can be affected if the receiving data rate is too low. That is, the received sound and video will be intermittent, garbled, or otherwise distorted

(3) Peaks in bandwidth usage. Even when the average output transmission bandwidth is close to the target bandwidth does not always guarantee that the data stream will be free of problems. For example, there can be bandwidth usage peaks at any instant during transmission. Also, if the packets are not homogeneously distributed during the transmission, i.e., a fairly constant time between the successive packets, packet clustering occurs that causes an increase or decrease of the bandwidth used at a given instant, this being the instantaneous bandwidth. As a result, the same problems described above for transmissions with mean bandwidth higher or lower than the target bandwidth can arise, although the adverse affects are experienced to a lesser degree.

Accordingly, it would be desirable to be able to better control the bandwidth usage for the transmission of packets containing any type of content. Prior attempts to solve the various problems discussed above typically enforce a maximum bandwidth. That is, the transmission protocol is such so as to intervene when a maximum value bandwidth is exceeded, but do not intervene when the bandwidth usage is lower than the maximum. Other existing solutions correct existing traffic streams. That is, a protocol is used to solve congestion problems caused by senders without inbuilt traffic control. Still other existing solutions discard packets when buffer space is exceeded. Some of the solutions of this type discard packets using an algorithm, such as the “leaky bucket” algorithm (Tanenbaum, Computer Networks, 3^(rd) Edition, p. 380, Prentice Hall). Other solutions permit a certain amount of burstiness in the output stream using an algorithm such as the “token bucket” algorithm (Tanenbaum, p. 381).

BRIEF DESCRIPTION OF THE INVENTION

In accordance with the invention, it has been discovered that the bandwidth can be held more closely to a desired target bandwidth value if the pause (wait time) between the successive packets is properly selected and the packets are transmitted using the selected wait time during the transmission of the content. A novel method and system are provided that determines and maintains the wait time between packets in response to selected input parameters of desired target bandwidth and size of the packets.

The method and system of the invention operate to transmit the data in a manner to control the bandwidth for the transmission of content by controlling the pause, or wait time, between the packets of the data stream. As part of the method and system, a novel algorithm has been developed and is implemented that relates the desired size (P) of the packets of a content to be transmitted to a desired target bandwidth (B_(T)) by selecting and controlling the wait, or pause, time pause (t_(w)), between the transmission of the packets. The invention can be implemented in software and/or hardware.

In a preferred embodiment of the invention, the precision of the bandwidth control is maximized by the use of the highest resolution clock or other timing device available at the sending device. This provides the best compensation for wait time rounding errors.

In a preferred embodiment of the invention, the wait time between packets is calculated based on a fixed packet size and target bandwidth.

The invention does not require or use feedback from the receiver devices. Therefore, it can be used for unicast, multicast and broadcast transmissions and with simplex, half-duplex and full-duplex media.

As compared to the existing transmission problem solutions discussed above, the invention causes data flow to tend towards target bandwidth, decreasing or increasing transmission speed as necessary. Also, the invention provides traffic control at the source so that the outgoing traffic is smoothly distributed and tends towards the target bandwidth. Further, the invention prevents excess packets by introducing pauses between packets, blocking the sender until the next packet is to be transmitted and never discards packets. Also, the present invention maintains a constant bandwidth usage with minimal burstiness.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects and advantages of the present invention will become more apparent upon reference to the following specification and annexed drawings in which:

FIG. 1 is a schematic diagram of a system implementation of the invention;

FIG. 2 is a flow chart of the process;

FIG. 3 is a flow chart showing the generation of various timing functions;

FIG. 4 is a diagram showing percentage error relative to a specified target bandwidth for an exemplary transmission bandwidth of up to 10 Mbps;

FIG. 5 is a diagram showing the percentage error relative to a specified target bandwidth for an exemplary transmission bandwidth of above 100 Mbps;

FIG. 6 is a diagram showing the percentage error relative to a specified target bandwidth for an exemplary transmission bandwidth of up to 1 Gbps;

FIG. 7 is a diagram showing various time relationships between packets;

FIG. 8 is a flow chart showing an alternate function for producing wait time of a fixed value between the start of sending of successive packets; and

FIG. 9 is a modification of the function of FIG. 8 introducing an error compensation mechanism.

DETAILED DESCRIPTION OF THE INVENTION

In the transmission of data packets, bandwidth is usually defined as the amount of data transmitted in a given time frame. Bandwidth control refers to the capability to control the bandwidth, i.e., the rate of transmission for a given amount of data. A significant value to evaluate bandwidth control quality is the mean (or average) bandwidth B_(M), that is, the arithmetic mean value about which the actual transmission rate centers during the entire transmission. The target bandwidth B_(T) is defined as the needed (selected) bandwidth for a given content transmission. In some cases, B_(T) is an amount of bandwidth that is sold or leased to a content producer by a broadcast facility.

If B_(T) is known, the mean bandwidth B_(M) can be defined by the following equation:

(B _(T)−ε)<B _(M)<(B _(T)+ε)  (Equation 1-1)

where

B_(T)=the target bandwidth

B_(M)=mean bandwidth

ε=error or deviation of B_(M) from B_(T)

The main goal of bandwidth control is to minimize the error ε between B_(M) and B_(T). To consider it from another perspective, Ε is the percentage error of the mean of the bandwidth actually transmitted relative to the desired target bandwidth B_(T), expressed in percentage terms as:

$\begin{matrix} {E = {{\frac{ɛ}{B_{T}} \cdot 100}\%}} & \left( {{Equation}\mspace{14mu} 1\text{-}2} \right) \end{matrix}$

It is also important to consider the amount of data transmitted in a fixed time window smaller than the time needed for the transmission of a complete content, that is, the instantaneous bandwidth, and to compare this value during the entire content transmission with the target bandwidth. This is necessary because if the instantaneous bandwidth values are largely different from the target bandwidth, the data transfer rate is oscillating, that is, the transmission is heterogeneous. This can happen even if the mean bandwidth B_(M) is equal or very near to the target bandwidth B_(T).

This heterogeneity in the bandwidth usage can be very difficult to manage at the receiving end, for routers and other routing devices, especially where the allowed target bandwidth B_(T) is fixed and cannot be exceeded, e.g., in the case of transmission of data by satellite transmissions.

A “constant” bandwidth can be theoretically obtained if the difference between the instantaneous bandwidth (measured in a time frame Δt), and the target bandwidth B_(T) tends to zero in a time t during the transmission. That is:

(B _(T)−ε)<B _([t,t+Δt])<(B _(T)+ε)  (Equation 1-3)

with ε and Δt tending to zero, and t_(start)<t<t_(end), and where t_(start): transmission start time; t_(end): transmission end time; Δt: measurement time frame, which must be less than the transmission duration; B_([t,t+Δt]): instantaneous bandwidth B measured in the interval included between t and t+Δt. The above is only a theoretical situation, not reproducible in the real world. Nevertheless, the bandwidth control described here is designed to approach as near as possible to this ideal solution, using the maximum precision supported by the sending device.

Another parameter that can be considered is the transmission burstiness, defined as:

$\begin{matrix} {{Burstiness} = \frac{B_{peak}}{B_{M}}} & \left( {{Equation}\mspace{14mu} 1\text{-}4} \right) \end{matrix}$

where B_(M) is the mean bandwidth of a transmission content, and B_(peak) is the highest of the absolute instantaneous bandwidth values measured during a transmission. That is:

B _(peak)=max(B _([t,t+Δt]))  (Equation 1-5)

Ideally, the burstiness should tend to one. That is, the bandwidth being used should be centered at B_(T). Note also that under the same conditions of burstiness, the transmission heterogeneity could be different, since no information is provided in this value about the recurrence of B_(peak). In fact, the burstiness value says how large the peak is relative to the mean transmission bandwidth B_(M), but not how many times the peak is repeated during a transmission. That is, a transmission can experience 1 or 1000 peaks, but the value B_(peak) is the same in most or all cases. Also, no information is provided about the heterogeneity of the transmission, that is, about the peak frequency.

Application programs making use of unreliable network protocols such as the User Datagram Protocol (UDP) for transmissions typically are not able to specify a target bandwidth B_(T) for a given transmission. As a consequence of the absence of direct control, data is sent at the maximum bandwidth allowed by the network interface. When the program communicates the instruction of sending a content to the network card, that content is sent at the maximum speed (bandwidth) allowed by the network card. For example, if the network card can handle 10 Mbps bandwidth, the content is fragmented into packets and these are sent at 10 Mbps on the network; there is no application level control.

In accordance with the invention, a wait, or paresidual time is imposed between successive packets of the transmission in order to control bandwidth usage and to achieve the selected target bandwidth B_(T). The method and system of the invention achieves bandwidth control by introducing this pause, in order that the average transmission bandwidth B_(M) is as near as possible to the target bandwidth B_(T). Also, all of the “instantaneous” bandwidth values measured during the transmission of the content are made to occur as closely as possible to the target bandwidth B_(T). For this reason, a high precision is needed in timing the time between packets, and the timing preferably should be as precise as possible. The needed precision needed for the wait time depends on the target transmission bandwidth B_(T). As described below, the higher the value of the target bandwidth B_(T), the greater the control of the precision of the pause between packets should be in order to maintain the deviation Ε from the target bandwidth to acceptable values for practical use.

Consider the following example of dividing the data of a content to be transmitted into packets of e.g. 8192 Bytes, and needing to transmit a fixed amount of data at a target bandwidth B_(T)=10 Mbps. This computes as the wait time, or pause, between every transmitted packet being 6.5536 milliseconds (8192 Bytes=8192*8=65536 bits. 10 Mbps=10000000 (ten millions) bits per second. Dividing 65536 by 10000000=>wait time (between packets)=0.0065536 seconds=6.5536 milliseconds). If the precision of the time measuring system for determining the wait time between packets is one millisecond, e.g., a one millisecond clock, then this time value has to be rounded down or up from the computed 6.5536 millisecond value so that the wait time will be 6 or 7 milliseconds. The rounding to 6 or 7 milliseconds will produce respective errors of −6.38% or 9.23% in average bandwidth usage from the specified B_(T)=10 Mbps. This example illustrates the need for a precise computation of the wait time intervals between packets during broadcasting. To ensure that the average bandwidth B_(M) is equal to the target bandwidth B_(T), theoretically the wait time must not be rounded. In practice, in some cases, this value must be rounded, due to software and hardware limitations. As described below, it is preferred that the highest precision supported by the sender device be used, and therefore that the achieved bandwidth control is optimized for the software and hardware configuration employed.

As described above, in order to provide high precision control, an important aspect to be considered is the time granularity (precision) for the measurement of the wait time between the successive transmitted packets. As an example, FIG. 4 shows the absolute percentage error Ε (logarithmic scale) on the specified (target) bandwidth B_(T) for a given transmission at bandwidth up to 10 Mbps, with a packet size of 8 KB. The upper curve shows the error with rounding of the wait time to the millisecond and the lower curve shows the error using rounding of the wait time to the microsecond. It can be seen that when the rounding is to the microsecond (higher precision) the error is less.

FIG. 5 shows, as an example, the absolute percentage error Ε (logarithmic scale) on the specified target bandwidth B_(T) for a given transmission at a bandwidth up to 100 Mbps, with a packet size of 8 KB. The upper curve shows the error with rounding of the wait time to the millisecond and the lower section shows rounding of the wait time to the microsecond. It can be seen that the percentage error Ε in actual bandwidth usage never exceeds 0.1%. By rounding the wait time to the millisecond the resulting error is significantly greater; the actual bandwidth usage would be 45-50% higher than the target bandwidth at a B_(T) of 50 Mbps and 35% lower at B_(T)=100 Mbps.

FIG. 6 shows the percentage error Ε on the specified bandwidth B_(T) for a given exemplary transmission (up to 1 Gbps), when rounding the wait time between the packets of the transmission to the microsecond, where the packet size=8 KB. The percentage error obtained when rounding to the millisecond is not shown on this graph. By rounding the wait time to the microsecond, the percentage error on the target bandwidth B_(T) up to 1 Gbps remains under 0.8% in the worst case. This means that the difference between mean bandwidth B_(M) and target bandwidth B_(T) would be under 8 Mbps. This might be considered to be acceptable for transmission speeds up to 1 Gbps. But using the 1 microsecond granularity would yield much higher and unacceptable errors for target bandwidths even significantly lower than 1 Gbps.

The packet size (P) plays an important role during transmission. In general, the larger the packet size, the smaller the percentage error of the target bandwidth B_(T) relative to the mean bandwidth B_(M), when there is rounding to at least the precision of a microsecond. This is due to the fact that if the packet size is increased, the number of packets for a given transmission content decreases and, consequently, the number of wait time occurrences between the packets of a given transmission decreases, causing the rounding error sum to decrease.

In the invention, the bandwidth in a transmission is controlled by selecting and placing wait time intervals t_(w) of a predetermined value between packets. It is preferred that the wait time interval t_(w) be computed with the highest precision possible on the sender device by using the highest resolution timing device available. As demonstrated above, at least microsecond granularity is preferable to guarantee an acceptable bandwidth control for transmission speeds in the Mbps range.

The algorithm applied to achieve the bandwidth control is as follows:

given the target bandwidth B_(T) and the packet size P, the wait time interval t_(w) between every packet is:

$\begin{matrix} {t_{w} = \frac{P}{B_{T}}} & \left( {{Equation}\mspace{14mu} 2\text{-}1} \right) \end{matrix}$

In operation, both B_(T) and P are provided as input parameters to the computer that controls the transmission. The target bandwidth B_(T) can be set by the person who wants to send a transmission through a user interface. For example, if one wants to send a content to a third person, a program can be made available where the “speed” at which the file is to be transmitted is entered by the user. That is, the target bandwidth B_(T) is given as an input parameter.

As to the packet size P parameter, typically the packet size is set when a program is installed to broadcast the transmissions, and then packet size is kept the same for all transmissions. The packet size can be, for example, contained in a configuration file. It also can be input as a separate parameter. In a typical use, the content to be sent and the target transmission bandwidth B_(T) are selected. Then the broadcast application reads the needed packet size P from the configuration settings, which was previously set by the broadcast application or was input. At this point, the broadcast application “fragments” the file to be transmitted into smaller packets. Typically, the header of these packets will specify the address of the receiver and information about the packet content. The broadcast application already knows the packet size, since it was read from the configurations or from the input before fragmenting the content to be transmitted into packets.

In use, the target bandwidth B_(T) selected for use with a broadcast application program is largely based on the transmission media to be used and other factors, such as the amount of bandwidth leased or purchased for use.

During the transmission of the packets a loop operation is repeated for every packet transmission as follows:

(1) obtain the actual time value t₁ (as start of packet transmission);

(2) send the packet;

(3) obtain the actual time value t₂ (after packet transmission);

(4) compute the time used to send the packet t_(used), where

t _(used) =t ₂ −t ₁  (Equation 2-2)

(5) compute a value t (residual time)

t=t _(w) −t _(used)  (Equation 2-3)

(6) Wait for t;

(7) go to step 1.

Referring to FIG. 7, this shows the various times. As seen, t_(w) is the time between the start (t₁) of two successive packets, while t is the time between the end (t₂) of one packet and the start (t₁) of the next packet. The residual time value t must be respectively based on the selected packet size P and target bandwidth B_(T).

The operation to send a packet of data is time consuming. That is, time t_(used) will be used to physically take a packet and send it on the network. To ensure that there is sufficient time for the wait time t_(w) to be achieved, the sender device needs to wait a residual time t after the send packet operation is completed. The computed wait time t_(w) between packets ensures that information will be sent at the needed target bandwidth. That is, the residual time t is the difference between t_(w) (wait between successive packets) and t_(used) (to send a packet).

FIG. 1 is a diagram that explains the transmission of the data packets. At the sending station there is a computer 10 that has a broadcast application program installed. The broadcast application program operates on a content 12 that is to be transmitted in data packets. The parameters of the transmission target bandwidth B_(T) and packet size P are input to the computer 10. As explained above, the value P of the packet size might already be known in the computer. It can be set if required. The computer computes the wait time t_(w) from the algorithm of Equation 2-1 and operates to control the transmission 16 of packets 18 (black bars), shown as having a controlled wait time t_(w) between the successive packets.

The packets 18 are received at a computer 20 that has a receiving application program installed. This program reassembles the received packets into a file that corresponds to the content file 12 that was sent. This is conventional.

FIG. 2 is a flow chart of the overall process. Here, in S1 and S2 the target bandwidth B_(T) and packet size P are input to the computer. In S3, the computer computes t_(w) in accordance with the algorithm of equation 2-1. The computed value t_(w) is used as a control parameter in S4 that is input to the broadcast application process S5. The t_(w) value is applied to the file to be sent as input at S6 to the broadcast process S5. The broadcast process S5 knowing the packet size from S2 and the wait time t_(w) from S3 transmits the S7 packets.

FIG. 3 shows the operation of the computer in performing the steps of the timing loop to obtain the residual time t as referred to above. At S101, the time t₁ at the start of transmission of a packet is determined and stored in S102. In S103, the packet to be sent is made available and is sent in S104. In S105, the end time t₂ of the transmission of the packet is determined and is stored in S106. In S108, the time quantity t_(used) in transmitting the packet is computed (S106 value minus S102 value) and is made available in S110.

In S111, the computed value of t_(w) (see S4) is used in S112 with t_(used) (from S110) to compute the residual time t (see Equation 2-3). The computed value of the residual time t is available in S114 as a time to be satisfied in S116 before transmission of the next packet is started at S101 and S102. The loop of FIG. 3 is repeated for each packet sent.

Using the algorithm of Equation 2-1 it is preferred that the facilities used to get the current time values t₁ and t₂ of Equation 2-2 and to wait for the residual time t of Equation 2-3 have at least microsecond granularity (precision or resolution). Making the granularity more precise decreases the error Ε of the actual mean bandwidth B_(M) relative to the target bandwidth B_(T) The most direct method to obtain the t₁ and t₂ values would be to get the actual time from the operating system, such as from its timing clock. However, this would imply that the operating system has a timer of microsecond precision. In the absence of this facility, a high precision hardware counter could be used. A counter is a general term used in programming to refer to an incrementing variable. Some systems include a high-resolution performance counter that provides high-resolution elapsed times. The counter values are managed by the computer central processing unit (CPU) and read by the operating system. Usually, the counter must be hardware controlled in a CPU-sharing operating system if other tasks, in addition to time computation, are carried out. If the increasing frequency of the counter, i.e., how many times in a second the count is increased, is known, it is possible to compute a time interval such as t_(used) by obtaining the counter value at two different times and dividing this difference by the counter frequency. As seen, it is desirable to use a high precision counter. Any reliable counter can be used, however, the highest resolution counter available on the device should be used in order to maximize the precision with which bandwidth is controlled.

Another key issue is how to suspend the program that sends the packets for a given residual time interval t. As shown above, after a packet is transmitted, the program must wait for the residual time t=t_(w)−t_(used) to have elapsed before sending another packet. If the broadcasting device does not have the necessary hardware and/or software facilities to accomplish the task of determining the residual time with the desired granularity, but provides at least a method to know the current time with the desired granularity, then other approaches can be used.

One approach, is shown in FIG. 8. Here the residual time t is supplied at step S201 and the determined value of t_(start) (start of the t_(w) function) and t_(now) (present time) are provided at S203 and S205. A time t_(elapsed) is computed in S207 as:

t _(elapsed) =t _(now) −t _(start)  (Equation 3-1)

A function (i.e., a software process) is implemented which, periodically, in a loop, compares in S209 the values of the difference between t_(elapsed) and the residual time t to wait before the next packet is sent. When the value of t_(elapsed) is equal or greater than the desired residual time t, the looping process ends and lets the program continue, sending a new packet. This approach provides high precision if the time measurements have high precision and the appropriate values, described below, are compared at frequent intervals.

The method of FIG. 8 can be described in an algorithm as follows:

S201 Get the desired residual time t (i.e., the how long the sending of packets must be suspended);

S203 Get the start time t_(start) (when the wait process is called);

Continue performing the following loop as often as possible:

S205 Get the current time t_(now);

S207 Compute t_(now)−t_(start)=t_(elapsed).

When t_(elapsed) is greater than or equal to t (S209), then exit the loop and let the program continue running.

When the process exits the loop, it means that (t_(now)−t_(start)) is greater or equal to the residual time t. Otherwise, the loop keeps on running. In some cases, it can happen that t_(elapsed) (t_(now)−t_(start)) is greater than the residual time t, that is, the process waited longer than the residual time t.

An improvement of the process of FIG. 8 is shown in FIG. 9, in which the same steps used in the FIG. 8 process are shown with the same reference numerals. In the process of FIG. 9, the small difference δ which can occur between t_(elapsed) and the residual time t is considered in each call of the process. First, the value of δ is set to zero in S200. Step S211 is added to the FIG. 8 process in which δ is computed. That is:

δ=t _(elapsed) −t  (Equation 3-2)

The value δ is stored in S213 for the next process call and subtracted in S210 from the next residual time t (passed as input to the process at the next call of starting the next t_(w) cycle).

The process of FIG. 9 dynamically compensates the rounding error by modifying the residual time t with the error δ. In this way, the time spent between sending one packet and the next tends toward t_(w) on the average, notwithstanding errors caused by rounding. The errors introduced in one cycle are compensated for in the subsequent cycles. With this correction, if the wait time t_(w) between packets (computed from P and B_(T)), which was in the process of FIG. 8 held constant during the entire transmission, changes dynamically in order to compensate for previous errors. During this period of error compensation the instantaneous bandwidth usage can exceed the target bandwidth B_(T).

This process of error correction process reduces the precision of the instantaneous bandwidth used in order to increase the precision of the mean bandwidth B_(M) used. The period for which the instantaneous bandwidth used exceeds the target bandwidth B_(T) depends on the rounding errors described above. The use of a high resolution clock or counter will limit this period. For this reason, this correction should be implemented only if it is possible and acceptable to exceed the target bandwidth for brief periods. This completes the bandwidth control process.

Considering the burstiness situation, it should be understood that if the timing rounding errors are not compensated, then the lowest possible limit to the burstiness is limited using the timing facilities provided by the sending device, but the average bandwidth may be lower than the target bandwidth B_(T). If the timing rounding errors are compensated, then the average bandwidth is as close as is possible to the target bandwidth using the timing facilities provided by the sending device, but the burstiness is greater than if error correction was not used.

Reliable protocols such as Transmission Control Protocol (TCP) send additional packets for acknowledgement of receipt, and retransmission of lost or corrupted data packets. The sender device cannot typically determine the number or size of additional packets sent, and so cannot control the bandwidth used. For this reason the invention is of significant benefit principally when used with unreliable packet based protocols.

The bandwidth control method and system of the invention can be applied to contents of whatever size. It is not necessary for the sender to know content size a priori. The only knowledge required up front is the size of the packets hereafter designated as P, and the target bandwidth. The content size only affects the transmission duration, and not the average bandwidth, if the process and/or device used to wait for the paresidual time between the packets is precise enough.

The method and system of the invention can be used in conjunction with existing traffic shaping solutions. Consider a network with many sender devices, many receiver devices and a traffic shaper between senders and receivers. If one or more of the sender devices produce bursty traffic, the traffic shaper will intervene to contain the resulting congestion by discarding packets. The introduction of the invention at one or more of the sender devices will reduce the burstiness of the output streams and so reduce the likelihood of congestion and packet loss.

Specific features of the invention are shown in one or more of the drawings for convenience only, as each feature may be combined with other features in accordance with the invention. Alternative embodiments will be recognized by those skilled in the art and are intended to be included within the scope of the claims. 

1. A method of using the wait time (t_(w)) between transmission of successive packets of known packet size (P) of a content to be transmitted to achieve a target bandwidth (B_(T)) during the transmission comprising the steps of: selecting a target bandwidth (B_(T)) sought to be achieved during the transmission; computing a wait time (t_(w)) between successive packets of the transmission using the algorithm ${t_{w} = \frac{P}{B_{T}}};$ and controlling the transmission of the packets using the wait time.
 2. The method as claimed in claim 1 wherein the computed wait time t_(w) that is used is rounded to a time unit.
 3. The method as claimed in claim 2 wherein the rounding to the time unit is accomplished by a counter.
 4. The method as claimed in claim 1 further comprising the step of: determining the start time t₁ of transmission of a packet; determining the end time t₂ of transmission of the packet, and determining the time used t_(used) in transmitting the packet as t₂−t₁.
 5. The method as claimed in claim 4 further comprising the steps of: (a) determining the time used (t_(used)) in the transmission of a packet; (b) determining a residual time (t) as t_(used)−t_(w); (c) waiting the time t between the end of transmission of one packet to the start of transmission of the next packet.
 6. The method as claimed in claim 5 further comprising the step of repeating steps (a), (b) and (c) for each packet transmitted.
 7. A method as in claim 5 wherein the residual time t is controlled by: determining a value of start time t_(start), of sending a packet a current time t_(now); performing a loop operation of: (a) computing a time t_(elapsed)=t_(now)−t_(start), (b) comparing t_(elapsed) to the residual time t and transmitting the next packet when the value of t_(elapsed)≧t.
 8. The method as claimed in claim 7 further comprising the steps of computing an error value δ=t_(elapsed)−t and subtracting the value δ from a later supplied value of t.
 9. A method as in claim 5 wherein the computed wait time t_(w) that is used is rounded to a time unit.
 10. A method as in claim 9 wherein the rounding to the time unit is accomplished by a counter.
 11. The method of claim 1, including the additional step of selecting the known packet size (P) of the packets to be transmitted.
 12. The method of claim 1 wherein the known packet size (P) is provided by an application.
 13. Apparatus for using the wait time (t_(w)) between transmission of successive packets of a content to be transmitted to achieve a target bandwidth B_(T) during the transmission comprising: a computer including a program to control transmission of a content in packets of data; means to input and receive parameters of the size (P) of the packets to be transmitted and of the desired target bandwidth (B_(T)); processing means to calculate a wait time (t_(w)) between successive packets of the transmission using the algorithm $t_{w} = \frac{P}{B_{T}}$ and control means to successively transmit the packets with the wait time t_(w) between the packets.
 14. Apparatus as in claim 13 wherein said computer further comprises: means for determining the start time (t₁) of transmission of a packet; means for determining the end time (t₂) of transmission of the packet, and means for determining the time used (t_(used)) in transmitting the packet as t₂−t₁.
 15. Apparatus as in claim 14 wherein said computer further comprises: first means for determining the time used (t_(used)) in the transmission of a packet; second means for determining a residual time t as t_(w)−t_(used); and wherein said control means operates to wait the residual time t between the start of transmission of one packet to the start of transmission of the next packet.
 16. Apparatus as in claim 15 wherein said first and second determining means operates to determine the residual time t for each packet transmitted and said control means operates to wait the residual time t between the start of transmission of one packet to the start of transmission of the next packet.
 17. Apparatus as in claim 16 further comprising means for controlling the residual time t by determining a value of start time t_(start), and a current time t_(now) performing a loop operation of: (a) computing a time t_(elapsed)=t_(now)−t_(start), and (b) comparing t_(elapsed) to the residual time t and transmitting the next packet when the value of t_(elapsed)≧t.
 18. Apparatus as in claim 17 further comprising means for computing an error value δ=t_(elapsed)−t and subtracting the value δ from a later supplied value of t.
 19. Apparatus as in claim 13 wherein said control means further comprises a counter that operates on a periodic basis to measure the wait time t_(w).
 20. Apparatus as in claim 13 wherein said computer operates said control means to compute the wait time t_(w) based on other measured times. 